Adding Hydrogen Significantly Increases the Stability of Catalysts in Shale-Gas Processing

Outcome/Accomplishment

Co-feeding hydrogen significantly reduces the accumulation of carbon, or coke, that can slow the refining of shale gas, according to research at the Center for Innovative and Strategic Transformation of Alkane Resources (CISTAR), an NSF-funded Engineering Research Center (ERC) based at Purdue University.

Impact/Benefits

Explanation/Background

With the recent discovery of abundant reserves of unconventional shale gas resources, the potential supply of natural gas has increased significantly. Shale gas primarily contains methane with a small amount of ethane and propane – and those three alkanes are feedstocks for the primary building blocks for the chemical industry. Therefore, with its growing availability, shale gas has the potential to bring about an energy revolution for the chemical industry.

But the processing of shale gas remains expensive and energy intensive. The first step involves dehydrogenation, where catalysts lose activity due to coke deposition, requiring periodic regeneration. Co-feeding H2 prolongs catalyst lifetimes, significantly reducing the costs. Stable performance with added hydrogen demonstrates that CISTAR-developed platinum-alloy catalysts are resistant to sintering, in which catalytic particles clump, causing loss of active surface for reaction. The CISTAR catalysts can now run for weeks, compared to about one day for current commercial catalysts.

Image

Location

West Lafayette, Indiana

e-mail

cistar@purdue.edu

Start Year

Energy and Sustainability

Energy and Sustainability Icon
Energy and Sustainability Icon

Energy, Sustainability, and Infrastructure

Lead Institution

Purdue University

Core Partners

University of New Mexico, Northwestern University, University of Notre Dame, University of Texas at Austin
Image

Outcome/Accomplishment

Co-feeding hydrogen significantly reduces the accumulation of carbon, or coke, that can slow the refining of shale gas, according to research at the Center for Innovative and Strategic Transformation of Alkane Resources (CISTAR), an NSF-funded Engineering Research Center (ERC) based at Purdue University.

Location

West Lafayette, Indiana

e-mail

cistar@purdue.edu

Start Year

Energy and Sustainability

Energy and Sustainability Icon
Energy and Sustainability Icon

Energy, Sustainability, and Infrastructure

Lead Institution

Purdue University

Core Partners

University of New Mexico, Northwestern University, University of Notre Dame, University of Texas at Austin

Impact/benefits

Explanation/Background

With the recent discovery of abundant reserves of unconventional shale gas resources, the potential supply of natural gas has increased significantly. Shale gas primarily contains methane with a small amount of ethane and propane – and those three alkanes are feedstocks for the primary building blocks for the chemical industry. Therefore, with its growing availability, shale gas has the potential to bring about an energy revolution for the chemical industry.

But the processing of shale gas remains expensive and energy intensive. The first step involves dehydrogenation, where catalysts lose activity due to coke deposition, requiring periodic regeneration. Co-feeding H2 prolongs catalyst lifetimes, significantly reducing the costs. Stable performance with added hydrogen demonstrates that CISTAR-developed platinum-alloy catalysts are resistant to sintering, in which catalytic particles clump, causing loss of active surface for reaction. The CISTAR catalysts can now run for weeks, compared to about one day for current commercial catalysts.